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王灿 教师名称：王灿 教师拼音名称：Wang Can 出生日期：1981-12-03 性别：男 职务：Vice director of department 职称：副教授 其他联系方式 邮编：300350 传真：022-85356231 通讯/办公地址：Building 43-B316, No.135, Ya Guan Road, Jin Nan District, Tianjin, China 移动电话：022-85356231 邮箱：wangcan@tju.edu.cn 基本信息 研究方向 获奖情况 论文成果 Dr. Can WANG is an associate professor in Tianjin University from July 2009. He received his B.A. degree from TongJi University in 2004 and his Ph.D. degrees from Tsinghua University in 2009. Now he is also the vice director of the department of environmental engineering in Tianjin University. His researches mainly focus on biofiltration of industrial contaminants, odor control system and the microbial community structure/function analysis. His detailed research interests cover: Selection/cultivation of special environmental contaminants degrading microorganisms; Application of thermophilic bacteria in biofilters; Development of effective biofiltration system for volatile organic compounds (VOCs) and odorants treatments; Analysis and optimization of the microbial community structure/functions in the biofilters.He has published 2 academic monographs and more than 60 papers on both the International and National Journals, including 35  SCI papers (the impact factors of 10 papers are higher than 5.0). There are more than 20 on-going projects, which were financed by government (Natural Science Foundation of China, or by Chinese Minister of Education) or international and national companies. The total research funding has exceeded 1,000,000 CNY.  Industrial Wastewater Treatment Tech. VOCs & Ordor & Bioaerosol Control Tech. Biopuringfication Tech. for Hadous and toxic contaminants Youth Talent of Chinese Society of Environmental Science Youth Science and Technology Phosphor of Tianjin [32]Wang Can, Xi Jin-ying, Hu Hong-ying. Identification and reduction of toxic products of chlorobenzene treatment by a combined UV-biofilter process. Journal of Biotechnology, 2008, 136(suppl. 1):S659. .2019 [31]Wang Can, Xi Jin-ying, Hu Hong-ying, Wen Xiang-hua. Biodegradation of gaseous chlorobenzene by white rot fungi. Biomedical and Environmental Science, 2008, 21(6):474-478. .2019 [30]Wang Can, Xi Jin-ying, Hu Hong-ying. A novel integrated UV-biofilter system to treat high concentration of gaseous chlorobenzene, Chinese Science Bulletin, 2008, 53(17):2712-2716. .2019 [29]Wang Can, Xi Jin-ying, Hu Hong-ying. Chemical identification and acute biotoxicity assessment of gaseous chlorobenzene photodegradation products. Chemosphere, 2008, 73(8):1167-1171. .2019 [28]Wang Can, Xi Jin-ying, Hu Hong-ying. Effects of nitrogen source, empty bed residence time and inlet concentration on performance of a biofilter for chlorobenzene removal. Engineering in life science. 2009, 9(2), 109-115. .2019 [27]Wang Can, Xi Jin-ying, Hu Hong-ying. Reduction of toxic products and bioaerosol emission of a combined UV-biofilter process for chlorobenzene treatment. Journal of air and waste management association. 2009, 59(4), 405-410. .2019 [26]Wang Can, Xi Jin-ying, Hu Hong-ying. Effects of operation conditions on removal rate constant and quantum yield of gaseous chlorobenzene in a photochemical reactor. Journal of air and waste management association. 2009, 59(4), 386-391. .2019 [25]Wang Can, Xi Jin-ying, Hu Hong-ying, Yao Yuan. Advantages of combined UV photodegradation and biofiltration processes to treat gaseous chlorobenzene. Journal of Hazardous Materials, 2009, 171(1-3), 1120-1125. .2019 [24]Wang Can, Xi Jin-ying, Hu Hong-ying, Yao Yuan. Effects of UV pretreatment on microbial community structure and metabolic characteristics in a subsequent biofilter treating gaseous chlorobenzene. Bioresource Technology. 2009, 100(23), 5581-5587. .2019 [23]Wang Can, Xi Jin-ying, Hu Hong-ying, Yao Yuan. Stimulative effects of ozone on a biofilter treating gaseous chlorobenzene. Environmental Science and Technology. 2009, 43 (24): 9407-9412. .2019 [22]Sun Liang, Wang Can*, Ji Min, Wang Fen. Achieving biodegradability enhancement and acute biotoxicity removal through the treatment of pharmaceutical wastewater using a combined internal electrolysis and ultrasonic irradiation technology, Frontier of Environmental Science and Engineering in China, 2011, 5 (3): 481-487. .2019 [21]Wang Can, Xi Jin-ying, Hu Hong-ying, Kang In-Sun. Modeling of a combined UV-Biofilter system treating gaseous chlorobenzene I. Model development and parametric sensitivity, Journal of Air and Waste Management Association, 2011, 61(3): 295-301..2019 [20]Sun Liang, Wang Can*, Ji Min, Liu Xiao Fang. COD removal and biodegradability enhancement of pharmaceutical wastewater by a multilayer internal electrolysis reactor, Asian Journal of Chemistry, 2012, 24, (1): 1112-116..2019 [19]Wang Can*, Xi Jin-ying, Hu Hong-ying, Kang In-Sun. Effects of design parameters and cost analysis of combined ultraviolet-biofilter systems treating gaseous chlorobenzene based on mathematical modeling, Frontier of Environmental Science and Engineering, 2012, 6(4):588-594. IF 1.67 引用次数：0(0).2019 [18]Huang Yao-Kun, Li Shuang, Wang Can*, Ji Min; Simultaneous removal of COD and NH3-N in secondary effluent of high-salinity industrial wastewater by electrochemical oxidation; Journal of Chemical Technology and Biotechnology, 2012, 87(7): 130-136. .2019 [17]Sun Liang, Wang Can*, Ji Min, Kong Xin. Treatment of mixed chemical wastewater and the agglomeration mechanism via an internal electrolysis filter, Chemical Engineering Journal, 2013, 215-216: 50-56. .2019 [16]Wang Can*, Kong Xin, Zhang Xin-Yue. Mesophilic and thermophilic biofiltration of gaseous toluene in a long-term operation: performance evaluation, biomass accumulation, mass balance analysis and isolation identification, Journal of Hazardous Material, 2012, 229-230: 94-99. .2019 [15]Kong Xin, Wang Can*, Ji Min. Analysis of microbial metabolic characteristics in mesophilic and thermophilic biofilters using Biolog plate technique, Chemical Engineering Journal, 2013, 230: 415-421..2019 [14]Wang Can*, Huang Yao-kun, Zhao Qing, Ji Min. Treatment of secondary effluent using a three-dimensional electrode system: COD removal, biotoxicity assessment, and disinfection effects, Chemical Engineering Journal, 2014, 243: 1-6. .2019 [13]Liu X，Li Y，Wang C*, Ji M．Comparison study on Cr (VI) removal by anion exchange resins of Amberlite IRA96, D301R, and DEX-Cr: isotherm, kinetics, thermodynamics, and regeneration studies．Desalination and Water Treatment，2015, 55(7): 1840-1850. .2019 [12]Liu X，Li Y，Wang C*，et al．Cr (VI) removal by a new type of anion exchange resin DEX-Cr: Adsorption affecting factors, isotherms, kinetics, and desorption regeneration．Environmental Progress & Sustainable Energy，2015, 34(2): 387-393..2019 [11]Hu Q Y, Li M, Wang C*, Ji M. Influence of powdered activated carbon addition on water quality, sludge properties, and microbial characteristics in the biological treatment of commingled industrial wastewater[J]. Journal of Hazardous Materials.2015, 295:1-8..2019 [10]Hu Q Y, Wang C*, Huang K X. Biofiltration performance and characteristics of high-temperature gaseous benzene, hexane and toluene[J]. Chemical Engineering Journal.2015, 279:689-695..2019 [9]Hu Q Y, Wang C*. Interaction of gaseous aromatic and aliphatic compounds in thermophilic biofilters[J]. Journal of Hazardous Materials.2015, 300:210-217..2019 [8]Wang C*, Chen WN, Hu QY, Ji M, Gao X. Dynamic fouling behavior and cake layer structure changes in nonwoven membrane bioreactor for bath wastewater treatment, Chemical Engineering Journal, 2015, 264(3): 462-469. .2019 [7]Wang D, Li M, Wang C*, Ji M. Optimization and effect of powdered activated carbon addition on commingled chemical industrial wastewater treatment in a sequencing batch reactor．Desalination and Water Treatment，2015, 56(1): 24-3..2019 [6]Fang S, Wang C*, Chao BT. Operationg conditions on the optimization and water quality analysis on the advanced treatment of papermaking wastewater by coagulation/Fenton process. Desalination and Water Treatment, 2016, 57(27): 12755-12762..2019 [5]Liu X，Wang C*, Zhou YN．Pretreatment of ultra-high concentration pharmaceutical wastewater by a combined Fenton and Electrolytic Oxidation technologies：COD reduction, biodegradability improvement and biotoxicity removal, Environmental Progress, 2016. .2019 [4]Wang D, Hu Q Y, Li M, Wang C*, Ji M. Evaluating the removal of organic fraction of commingled chemical industrial wastewater by activated sludge process augmented with powdered activated carbon[J]. Arabian Journal of Chemistry.2016, 9(2):1951-1961..2019 [3]Shi S, Wang C*, Fang S, Jia MH, Li XG. Removal performance and water quality analysis of paper machine white water in a full-scale wastewater treatment plant, Environmental Technology, 2017, 38(11): 1443-1451. .2019 [2]Wen N J, Liu H, Fu Y, Wang C* Optimization and influence mechanism of sampling and analysis of airborne endotoxin based on Limulus amebocyte lysate assay, Aerosol and Air Quality Research, 2017, 17: 1000-1010..2019 [1]Sun X, Wang C*, Ji M. Production and release of microcystin-LR during treatment using chemical algicide, Fresenius Environmental Bulletin, 2017, 26(1): 572-578.2019 教育经历 2004.9-2009.7 Tsinghua University, China   Environmental Engineering   博士 2000.9-2004.7 Tongji University, China   Environmental Engineering   学士 工作经历 2009.7 -2019.12 |School of enivronmental science and engineering|Tianjin University 团队成员 Environmental Biological Technology and Bio-Safety Control 团队名称:Environmental Biological Technology and Bio-Safety Control 团队介绍:The laboratory of Environmental Biological Technology and Bio-Safety Control is dedicated to fundermental and advanced studies on natural and eco/biological system, biological engineering processes for environmental pollution control and harmful microorganisms.  Research Interests covers the following:Biological technologies and process for Volatile organic compounds (VOCs) control.Air disinfection and bioaerosol control technologies for safety.Enhanced biological technologies for refractory organic wastewater treatment.Exploitation and utilization of environmental microorganisms and microbial products.Regulate and control of microbial community and function.